Sterile or specific pathogen free environment products

ABSTRACT

Methods of maintaining or providing sterile or specific pathogen free environments are disclosed. The methods involve the use of semi-permeable membrane materials between the sterile or pathogen free environment and surrounding potentially hostile environments.

This is a divisional of application Ser. No. 08/237,719 filed Apr. 29,1994 (now U.S. Pat. No. 5,610,070) which is a continuation ofapplication Ser. No. 07/940,969 filed Nov. 5, 1992 (abandoned).

The present invention relates to sterile environment products and moreparticularly but not exclusively to such products for use in medical,horticultural, industrial, agricultural and like establishments in whicha specific pathogen free (SPF) environment is required.

For the avoidance of doubt, the term Specific Pathogen Free (hereinabbreviated to SPF) shall include environment free not only of specificpathogens but also of specific toxins and toxic substances havingmolecular weight above the specific exclusion point (cut-off point) ofcertain semi-permeable membranes referenced hereinafter.

In our co-pending PCT patent application number PCT/GB/89/01119(publication number WO/90/03333) there is disclosed a water purifyingsystem for providing non-toxic solutions of water-soluble solids fromwater sources which may contain undesirable micro-organisms.

The present invention seeks to apply similar principles to thosediscussed in the above application for the purposes of simplifyingcertain medical and industrial procedures and improving availability ofdrugs where limited storage or other space is available or where suchdrugs in solution may become unstable. The invention may also contributeto reducing costs of distribution and supply in sterile form.

The invention also seeks to provide improved procedures for use inhorticulture, fisheries (including establishments breeding and/orrearing other aquatic or marine lifeforms), and the like and to provideimprovements in in-vitro and cell culture systems including tissueculture and organ culture for example.

All of the above mentioned systems have one principal difficulty whichis to maintain sterility in the solution or environment whileintroducing secondary soluble substance or substances such as drugs ornutrients to that solution and maintaining an SPF environment.

It is one object of the present invention to provide a method andequipment for alleviating this difficulty.

According to one aspect of the present invention there is provided amethod of introducing a secondary substance into a liquid SPFenvironment comprising the steps of interfacing the SPF environment witha surrounding environment by means of a semi-permeable membrane andintroducing said secondary substance on an opposed side of the membraneto the SPF environment whereby the secondary substance(s) may passthrough the membrane into the SPF environment while contaminants ofhigher molecular weight are excluded.

For the avoidance of doubt the term contaminant of higher molecularweight includes micro-organisms and soluble toxic substances.

According to another aspect of the present invention there is providedan in-line connector for use with (e.g.) drip-sets, the connectorcomprising a first port for connection to a source of sterile liquid, asecond port for connection to a transfer tube or injection module and athird port through which secondary substances may be introduced, saidfirst and second ports being connected to said third port by way of asemi-permeable membrane whereby drugs and/or nutritional solutes may beintroduced to solution in a transfusing liquid without introducingexternal contaminants.

According to a further aspect of the present invention there is provideda method of in-vitro culture comprising the steps of enclosing cell(s)to be cultured in a sealable receptacle which has at least a portioncomprising a semi-permeable membrane and contacting an external surfaceof the semi-permeable membrane with a solution containing nutrients orother secondary substances for treatment of the culture whereby suchnutrients or secondary substances may pass into the culture solutionwithout contaminants of higher molecular weight being introducedthereto.

The present invention will now be described by way of example only withreference to the accompanying drawings of which:

FIG. 1 is a schematic diagram of a drip set including a connector inaccordance with the present invention; and

FIG. 2 shows a cell culture system in accordance with the invention.

Reference to the specification of PCT patent application numberPCT/GB/89/01119 will show the kind of contaminants which may be excludedfrom solutions by use of semi-permeable membranes of different types.Such contaminants include (but are not limited to) microbial pathogensand other micro-organisms, microbial spores and cysts and the likeincluding the exclusion of specific cell or tissue types.

It will be appreciated that while the invention of the citedspecification is directed to providing solutions having improvedsterility from water which may be severely contaminated, the principleof reducing disease or contamination risks is necessary in otherenvironments.

For example, it is often desirable to introduce one or more drugs into apatient (whether human or animal) by way of a drip set. Unless each drugand combination of drugs likely to be of use are stored in packs readyfor use, some delay may occur in obtaining suitable sterile supplies.Further, as is well known, certain drugs deteriorate during storage andcertain combinations of drugs in solution may over a period of timeinter-react and become ineffective.

Although the term drip set is used herein (as a reference to intravenousinfusion sets) and drip sets are referred to throughout thespecification, the invention is not limited to drip sets per se and itwill be appreciated that the use of the invention extends to for examplenaso-gastric feeding tubes, perfusion solutions and the like.

Thus, referring to FIG. 1, we provide a connector 1 for insertion inline between a sterile (saline) solution pack 2 and a feeder tube 3. Thepack 2 is of standard form and will have been prepared under sterileconditions and may have undergone subsequent sterilisation processessuch as by irradiation for example.

The connector 1 comprises a first connector port 4 for connection to theoutlet of the pack 2 and a second connector port 5 for connection to thefeeder tube. The body 6 of the connector 1 is of translucent plasticsmaterial and serves to provide visibility of the drip flow.

The ports 3 and 4 form a part of a first chamber 7 which is separatedfrom a second chamber 8 by means of a semi-permeable membrane 11 ofknown material (for example Visking (trademark) membrane) in the wall ofthe body 6. The second chamber 8 has an inlet port 9 which may be cappedby a plug 10 as shown in the drawing. In use, the drip set is assembledin traditional manner connecting the pack 2 outlet by way of theconnector I to a feeder tube and injection device for introducing thesolution to a patient. Additive drugs may now be introduced through theinlet port 9. The drug introduced into the inlet port 9 may now diffusethrough the membrane 11 into the drip solution and thence to thepatient.

While it will be realised that as far as practicable, substancesintroduced to the chamber 8 should be sterile and preferably handledaseptically, the semi-permeable membrane 11 will ensure that sterilityof liquids held in the pack 2 is maintained.

Although as thus far described, it is assumed that the contents of thepack 2 are a saline solution, it will be appreciated that othersolutions may be used. However, the ability to introduce drugs ofdiffering kinds into appropriate isotonic or standard infusions such assaline solution or dextran solution at the point of administration hasseveral benefits.

Firstly, it is unnecessary to hold in store large quantities of premixeddrugs in sterile solution since each drug or combination of drugs may beheld in a stable form which is not necessarily in sterile condition.Quantities of sterile infusion solutions only need be held. Thusstorage, transportation and deterioration costs may be reduced.

Further, where unusual combinations of drugs are required these can beprovided without time wastage in obtaining supplies specially preparedin sterile conditions.

Yet another advantage is noted in that regardless of environmentalhostility, provided that the primary injection fluid is sterile abinitio, introduction of further substances to that solution may occurwithout introduction of pathogens from the environment.

It will also be realised that there is a reduction of risk to personsadministering drug combinations to patients infected with dangerouspathogens since the need to open a line is reduced thus the chances ofsuch persons coming into contact with infected body fluids iscorrespondingly reduced.

Where the primary requirement is for protection of administeringpersons, the semi permeable membrane may be selected to have a cut-offpoint slightly below the molecular weight of the infectingorganism/virus whereby treatment substances of only slightly lowermolecular weight than the infecting organism may be used.

In an alternative method of using the connector 1, in circumstanceswhere a drug combination is most effective when mixed at the lastpossible moment, the inlet port 9 may be replaced by a connector (notshown) to which a second pack containing a predetermined differentsolution may be connected. Thus by providing the connector in the formshown, intermixing of drugs may occur temporally close to the time ofadministration thus avoiding possible adverse inter reaction of drugcombinations.

It will also be appreciated that the system may be employed to addspecific drugs or additives prior to administration.

A further benefit of the present invention will be appreciated whereslow continuous administration of (e.g.) drugs would be beneficial tothe patient. In such cases, a coated dry drug may be added at the port 9so that the combination of the coating and slow membrane passagerestricts the rate at which the drug is administered. The same resultmay be achieved by selecting a membrane or composite membrane to have aspecifically slow transfer rate, possibly by restricting the surfacearea of the membrane for example. In a further alternative, a pluralityof membranes separated by a short distance may be employed so thatcumulative transfer rates reduce the rate of drug infusion.

A further adaptation for use independently or in combination with theabove utilises selective ion membranes and/or selective ion powders toensure the exclusion of specific chemical groups (for example sodiumions).

The progress hereinbefore described and other aspects of the inventionas hereinafter described may be used in industrial applications wheresubstances may be introduced to a sealed liquid container withoutintroduction of unwanted foreign substances of higher molecular weight.In industrial situations it will be appreciated that the substance towhich other substances are introduced may be (e.g.) a solvent or otherliquid as an alternative to the sterile water/saline solution used inmedicinal applications.

It will be appreciated that while as herein described, saline solutionsand drug solutions have been specifically mentioned, the invention maybe applied equally to other solutions in common usage includingdistilled water and may be used with blood and blood substitutes.

In a further development of the system, particularly to reduce risk tocarers when dealing with patients infected with dangerous pathogens, apermanent "injection" point may be provided for insertion for exampleinto a vein in the patients wrist. It is now common to provide aninjection point in medium to long term patients in hospitals byinserting a needle attached to a short tube which is capped. The deviceis then strapped to the patient providing a connection point for anoutlet from a syringe without necessitating the use of further needlesand thus reducing discomfort to the patient from a large number ofinjection sites. This modification may be applied to the form of devicesometimes referred to as a "Butterfly".

The present invention provides a similar arrangement comprising a needleattached to a small chamber, the tube of the needle being linked to thepot by way of a semi permeable membrane. Thus, the possibility of aninfected patients blood leaking back through the connection port issignificantly reduced.

It will be appreciated that the port 9 may have a control mechanismbelow the membrane whereby transfer of substances through the membraneto the chamber 7 thereby permitting additive drug dosages for example tobe commenced and stopped as necessary.

Turning now to FIG. 2, the invention may find use in in-vitro culturesystems, tissue culture systems and organ culture systems (includingplant, animal and bacterial culture systems) where it is desired toculture cells in sterile conditions but where additional substances suchas nutrients of differing kinds are required to be introduced.

Additional substances as referred to above may include (but are notlimited to) hormones, growth factors, mineral substances, gases andinsecticides or fungicides.

In this case, the initial cell or cells to be cultured are introducedinto a sealable package which has been previously sterilised, theintroduction being carried out in as near sterile conditions aspossible. An initial supply of nutrient solution may be introduced tothe package concurrently or may previously have been packaged within,prior to sterilisation for example by irradiation.

The package has at least one section comprising a semi-permeablemembrane such that by placing the package in a solution of higherconcentration than the nutrient solution contained within, nutrients maypass through the membrane into the culture.

As nutrients are taken up in the culture, the package may be placed innutrient solution so that nutrients from the solution may be added tothe culture without further introducing undesirable contaminants such asbacteria. It will of course be realised that substances other thannutrients may be introduced using this method provided that suchsubstances are of lower molecular weight than the cut-off point of themembrane.

In a specific alternative to an immersible package, referringspecifically to FIG. 2, a culture dish 31 containing a sterile nutrientsolution 32 to which a cell or cells to be cultured have been added iscapped by a semi-permeable membrane 33. Fresh nutrients 34 (or drugtreatments and other substances) in solution are added above themembrane 33 as required and permeate through the membrane to thesolution 32 thereby maintaining or modifying the balance of nutritionalor other concentration therein. Substances of lower molecular weightthan the cut-off point of the membrane 33, for example excreta whoseremoval may benefit the culture, may diffuse out of the culture mediumin the same manner. Such substances include Urea and gaseous materialssuch as armnonia.

Higher molecular weight substances (including the cell or cells underculture) are retained within the culture dish 31 by the membrane 33.Thus as with the drug/nutrient administration system of FIG. 1hereinbefore described the culture medium 32 retains its sterilityregardless of the hostility of the surrounding environment and/or thenature and sterility of secondary substances being introduced.

It will be appreciated that gases in solution or in gaseous state may bediffused through the semi-permeable membrane materials and such gasesare included within the term secondary substances. Both removal andintroduction of such gases is possible where the culture might bebeneficially so treated.

This method of protection of cell cultures may also be applied in asimilar way to facilitate the propagation of plants in sterileconditions.

For example using tissue culture to reproduce plants from small sectionstaken from a healthy parent, new plants may be grown inside a SPFenvironment while nutritional elements can still be added and organisms(including insects, fungal spores and the like) are excluded.

In a further development of the plant culture system, seeds may beencapsulated in a semi permeable membrane bag or the roots of seedlingsmay be encapsulated such that the further development of plantstherefrom may proceed without interference from certain adverseinfectious agents such as fungi or bacteria present in soils affectingyoung tissue.

Specific nutrients or symbiotic organisms may be encapsulated around theroot system or seed to ensure clean, rapid development of the youngplant and specific helpful bacteria may also be introduced. For example,encapsulating cellulolytic bacteria which can "feed" on the cellulosemerfibrane while fixing nitrogen can improve the growth rate of theyoung plants by ensuring a ready supply of nitrogenous compounds. Suchbacteria will over a predetermined period also dissolve the surroundingmembrane when the plant is sufficiently developed.

Examples of cellulolytic bacteria which could perform this function arereported in an article in "Science", Volume 242 at page 1157.

Other uses for SPF environments provided by use of semi-permeablemembranes can be shown to include for example fish farming where fungalinfection is a possible danger. Thus by providing an environment whichis known to be initially free of specific pathogens and organisms (forexample in a plastics enclosure which isolates the SPF environment fromthe surrounding environment) and providing an interface between the SPFenvironment and the surrounding environment which comprises one or moresemi-permeable membranes it is possible to maintain substantially SPF.

The environment would normally be water for example into which nutrientsmay be introduced, the nutrients then passing into the environment whilecontaminants are effectively excluded. Waste products of low molecularweight may also diffuse from the enclosure into the surroundingenvironment.

For example fish held within an individual environment may be preventedfrom damage by contaminating organisms and fungal infections.

The method may also be of use in similar environments where undesirableorganisms may adversely affect the survival chances of the end animalproduct. For example, not only fish per se but also fish eggs and otherlarval forms may benefit from protection at an early stage in their lifecycles.

Further, crustacea including small crabs, prawns and the like and otherinvertebrates may be reared in a protected environment even if only invery early stages.

In order to demonstrate the efficacy of the invention, the followingtest has been carried out. 10 mL of phenol red solution placed in ameasuring cylinder and a sample taken for absorption at 550 nm. 10 mLwater placed inside a six inch length of dialysis tubing having adiameter of 1.6 cm which was then sealed and immersed in the phenol redheld in the measuring cylinder.

Samples were taken from the measuring cylinder and from the dialysistubing and the absorbance at 550 nm determined after appropriatedilution. The results are given in the following table:

    ______________________________________                Absorbance at 550 nm    Time (h)      Inside tubing                            Outside tubing    ______________________________________    0             0         2.57    0.5           0.19      2.59    0.75          0.32      2.60    1.75          0.56      2.32    3.25          0.92      2.19    6.0           1.49      2.11    24.0          1.96      2.05    ______________________________________

Phenol red has a molecular weight of 354 whereas the molecular weightcut-off of the tubing used was 12,000. The test therefore shows thatthis low molecular weight substance can penetrate into the dialysistubing, equilibrium being reached after between 6 and 24 hours. Earliertests reported in the referenced pending PCT patent Application haveshown that bacteria, viruses and other organisms cannot penetrate suchtubing. Accordingly the test demonstrates that low molecular weightsubstances may be added aseptically to a solution contained withindialysis tubing without actually breaking the seal of such tubing.

A further aspect of the invention provides protection for operativesinvolved in the testing and identification of potentially toxicsubstances.

The safe handling of potentially infectious biological tissues andfluids by personnel who have to test these materials may be improved byuse of the methods of the present invention. To provide protection tosuch personnel, fluid samples or tissue samples are collected into acontainer comprising at least in part a membrane having an appropriatecut-off selected to retain the sample.

The container may have a fixed known volume enabling quantitativeanalysis to be carried out. Substances of interest which are the subjectof these tests but not micro-organisms will be below the selectedmolecular weight cut off of the membrane and can therefore diffusethrough the membrane. Test reagents may also be below the molecularweight cut off of the membrane.

Analysis can be carried out by way of the following examples:

The container may be in direct contact with the desired test reagent andthe test result directly read. For example faecal material for test foroccult blood may be contained within the sealed container. Contactingthe membrane with a test reagent allows the reagent to pass into thecontainer to react with occult blood present thereby indicating thepresence or absence of same. The operative is protected from any harmfulpathogens within the faecal material which are prevented from passingthrough the membrane material.

A further benefit of this kind of testing may also be apparent in thatseveral containers may be placed in a common solution of reagent withoutrisk of cross contamination of samples.

Alternatively, the container may be immersed in a known volume of liquidreagent and after a pre-determined period of time allowing substances todiffuse into the liquid, testing may be completed without risk to theoperator. Example suitable for this kind of testing include the testingof blood or urine for the presence of electrolytes such as potassium orsodium. Similarly, sugar in urine tests may be carried out eitherqualitatively or quantitatively. Visual assessment of test results willbe possible in many cases particularly if the test reagent is applieddirectly to the outside of the membrane.

Results can be achieved by test substances diffusing into the package orinto the sealed chamber, the container including a transparent ortranslucent section to allow visual inspection of (e.g) colour changes.

In a further use of the invention, enclosing objects to be disinfectedinside a sealed container either partially or totally comprised ofsemi-permeable membrane material and including a disinfectant solute,permits disinfection even if doubts exist as to the sterility of thesolution to be used in the disinfection process.

Thus, contacting the membrane material with a solution (e.g) watercauses the solute to be disolved to commence disinfection, and reducesthe need for disinfectant solutions to be held and stored in quantityfor long periods.

Examples of objects which may be so sterilised include contact lenseswhich may be enclosed in a sealable package and left in solutionovernight. Sterile saline solution for washing of the disinfectingobject may be prepared at the same time by use of a second package whichmay be linked to the first package in such a way as to permit the lensto be transfered to the saline solution without further handling.

A similar principle may be applied in maintaining or reinforcing thesterility of instruments to be used in operating theatres whereby theinstrument may be enclosed 3.n a package with a solute, the packagebeing of semi-permeable membrane material. Standard radiation methods ofproviding primary sterilisation may be used. However, prior to use ofthe instrument, the package may be placed in water in case the packaginghas been damaged in transit.

In this case a sterility check may be carried out by adding a highmolecular weight dye, for example blue dextran, to the water so that anycolour presence inside the sterile package indicates possiblecontamination.

We claim:
 1. A method of testing a potentially infectious substanceselected from the group consisting of blood, tissue, and otherbiological samples, said method comprising the steps of:(a) placing thepotentially infectious substance to be tested in a container of which atleast a part of the container is formed of a semi-permeable membrane,the semi-permeable membrane having a molecular weight cut-off such thatviruses and other potentially infectious organisms are retained withinthe container by virtue of having a molecular weight higher than themolecular weight cut-off; (b) closing the container; and (c) contactingthe semi-permeable membrane with at least one reagent solution therebyallowing non-infectious components of said substance to pass through themembrane and react with the reagent solution, therefore allowing thetest to be performed.
 2. A method of testing as claimed in claim 1further characterized by said container containing a predeterminedvolume of a substance to be tested, said substance being in contact viathe semi-permeable membrane with a predetermined volume of said reagentsolution.
 3. A method of testing as claimed in claim 1 furthercharacterized in that a plurality of said containers are tested in acommon solution of test reagent, whereby a plurality of substances maybe simultaneously tested without risk of cross contamination.
 4. Amethod of testing a potentially infectious substance selected from thegroup consisting of blood, tissue, and other biological samples, saidmethod comprising the steps of:(a) placing the potentially infectioussubstance to be tested in a container of which at least a part of thecontainer is formed of a semi-permeable membrane, the semi-permeablemembrane having a molecular weight cut-off such that viruses and otherpotentially infectious organisms and toxins thereof are retained withinthe container by virtue of having a molecular weight higher than themolecular weight cut-off; (b) closing the container; and (c) contactingthe semi-permeable membrane with at least one reagent solution therebyallowing non-infectious and non-toxic components of said substance topass through the membrane and react with the reagent solution, thereforeallowing the test to be performed.
 5. A method of testing as claimed inclaim 4 further characterized by said container containing apredetermined volume of a substance to be tested, said substance beingin contact via the semi-permeable membrane with a predetermined volumeof said reagent solution.
 6. A method of testing as claimed in claim 4further characterized in that a plurality of said containers are testedin a common solution of test reagent, whereby a plurality of substancesmay be simultaneously tested without risk of cross contamination.
 7. Amethod of introducing a secondary substance in solution into a liquidspecific pathogen free (SPF) environment, said SPF environmentcontaining living tissue selected from the group consisting of plantseeds, plant seedlings, plant cuttings, plants, root system of plantseedlings, root systems of plant cuttings, root systems of plants, fisheggs, larval forms of fish and fish, said method comprising the steps ofinterfacing the SPF environment with a surrounding environment by meansof a semi-permeable membrane and introducing said solution on an opposedside of the membrane to the SPF environment whereby the secondarysubstance in solution may pass through the membrane into the SPFenvironment while contaminants of higher molecular weight are excluded.8. A method of treating an in-vitro culture comprising the steps ofenclosing cell(s) to be cultured in a sealable receptacle which has atleast a portion comprising a semi-permeable membrane, said membranehaving a molecular weight cut off such that viruses and otherpotentially infectious organisms are unable to pass through themembrane, sealing said receptacle, and contacting an external surface ofthe semi-permeable membrane with a solution containing nutrients orother secondary substances for treatment of the culture whereby suchnutrients or secondary substances may pass into the culture solutionwithout contaminants of higher molecular weight being introducedthereto, and whereby said semi-permeable membrane provides the onlymeans for introducing nutrients or secondary substances into theculture.
 9. An in-line connector for use with drip-sets, the connectorcomprising a first port for connection to a source of sterile liquid, asecond port for connection to a transfer tube or injection module and athird port through which secondary substances may be introduced, saidfirst and second ports being connected to said third port by way of asemi-permeable membrane whereby drugs and/or nutritional solutes may beintroduced to the solution in a transfusing liquid without introducingexternal contaminants.
 10. An in-line connector as claimed in claim 8further characterized in that the membrane is selected to restrict therate of flow of the secondary substance whereby the rate of transfer ofthe secondary substance to the transfusing liquid is controlled.
 11. Anin-line connector as claimed in claim 9 further characterized in that asecond semi-permeable membrane spatially separated from the first saidmembrane is provided whereby the rate of flow of the secondary substanceis restricted whereby the rate of transfer of the secondary substance tothe transfusing liquid is controlled.
 12. An in-line connector asclaimed in claim 9 characterized in that the first and second ports areconnected to a first chamber and the third port is connected to a secondchamber, the first and second chambers being connected by the semipermeable membrane.
 13. An in-line connector as claimed in claim 12further characterized in that at least the first chamber is oftranslucent material whereby the rate of flow of the transfusing liquidis visible.
 14. A method of disinfecting objects comprising insertingthe object in a sealable package at least partially formed ofsemi-permeable membrane material, enclosing a disinfectant solute withinthe package, sealing the package and contacting the semi-permeablemembrane with a solution whereby the solution enters the package toeffect disinfection while contaminants of higher molecular weight thanthe cut-off point of the membrane material are excluded.
 15. Aninjection device for insertion into a patient comprising injection meansfor subcutaneous insertion, means for temporarily attaching theinjection device to a patient and a chamber into which drugs or otherinjectable solutions may be inserted characterized in that the injectionmeans is connected to the chamber by way of a semi-permeable membrane toprevent contaminated body fluids from leaking back to the chamber.